/************************************************************* throttle control ****************************************************************/ // user input: // ----------- void output_manual_throttle() { rc_3.servo_out = (float)rc_3.control_in * angle_boost(); } // Autopilot // --------- void output_auto_throttle() { rc_3.servo_out = (float)nav_throttle * angle_boost(); // make sure we never send a 0 throttle that will cut the motors rc_3.servo_out = max(rc_3.servo_out, 1); } void calc_nav_throttle() { if(altitude_sensor == BARO) { nav_throttle = pid_baro_throttle.get_pid(altitude_error, delta_ms_fast_loop, 1.0); // limit output of throttle control nav_throttle = throttle_cruise + constrain(nav_throttle, -50, 100); } else { // SONAR nav_throttle = pid_sonar_throttle.get_pid(altitude_error, delta_ms_fast_loop, 1.0); // limit output of throttle control nav_throttle = throttle_cruise + constrain(nav_throttle, -60, 100); } } float angle_boost() { //static byte flipper; //float temp = 1 / (cos(dcm.roll) * cos(dcm.pitch)); float temp = (1.0 - (cos(dcm.roll) * cos(dcm.pitch))); temp = 1.0 + (temp / 1.5); // limit the boost value if(temp > 1.4) temp = 1.4; return temp; } /************************************************************* yaw control ****************************************************************/ void output_manual_yaw() { if(rc_3.control_in == 0){ clear_yaw_control(); } else { // Yaw control if(rc_4.control_in == 0){ //clear_yaw_control(); output_yaw_with_hold(true); // hold yaw }else{ output_yaw_with_hold(false); // rate control yaw } } } void auto_yaw() { output_yaw_with_hold(true); // hold yaw } /************************************************************* picth and roll control ****************************************************************/ /*// how hard to tilt towards the target // ----------------------------------- void calc_nav_pid() { // how hard to pitch to target nav_angle = pid_nav.get_pid(wp_distance * 100, dTnav, 1.0); nav_angle = constrain(nav_angle, -pitch_max, pitch_max); } // distribute the pitch angle based on our orientation // --------------------------------------------------- void calc_nav_pitch() { // how hard to pitch to target long angle = wrap_360(nav_bearing - dcm.yaw_sensor); bool rev = false; float roll_out; if(angle > 18000){ angle -= 18000; rev = true; } roll_out = abs(angle - 18000); roll_out = (9000.0 - roll_out) / 9000.0; roll_out = (rev) ? roll_out : -roll_out; nav_pitch = (float)nav_angle * roll_out; } // distribute the roll angle based on our orientation // -------------------------------------------------- void calc_nav_roll() { long angle = wrap_360(nav_bearing - dcm.yaw_sensor); bool rev = false; float roll_out; if(angle > 18000){ angle -= 18000; rev = true; } roll_out = abs(angle - 9000); roll_out = (9000.0 - roll_out) / 9000.0; roll_out = (rev) ? -roll_out : roll_out; nav_roll = (float)nav_angle * roll_out; } */